Rev. Bras. Hematol. Hemoter. vol.35 número4

Case Report

290 Rev Bras Hematol Hemoter. 2013;35(4):290-2

Shwachman-Diamond syndrome: irst molecular diagnosis in a Brazilian child

Cresio Alves1

Julia Constança Fernandes1 Silvana Sampaio1

Raquel de Melo Alves Paiva2 Rodrigo Tocantins Calado2

1_{Universidade Federal da Bahia – UFBA,} Salvador, BA, Brazil

2_{Faculdade de Medicina de Ribeirão Preto} da Universidade de São Paulo - USP, Ribeirão Preto, SP, Brazil

Conlict-of-interest disclosure:

The authors declare no competing inancial interest

Submitted: 3/5/2013 Accepted: 6/4/2013

Corresponding author: Cresio Alves

Hospital Universitário Prof. Edgard Santos – HUPES

Unidade de Endocrinologia Pediátrica Rua Plinio Moscoso - 222/601 40157-190 Salvador, BA, Brazil Phone: 55 71 3357-5500 [email protected]

www.rbhh.org or www.scielo.br/rbhh

DOI: 10.5581/1516-8484.20130058

Introduction

The Shwachman-Diamond Syndrome (SDS) is a rare autosomal recessive disorder characterized by exocrine pancreatic insuficiency, intermittent or persistent neutropenia and skeletal changes(1-4). Other clinical characteristics include immune system, hepatic and cardiac

abnormalities and predisposition to leukemia(1)_.

The syndrome was irst described in 1964 by Shwachman et al.(5). However, its molecular basis was only identiied in 2002; this demonstrated that approximately 90% of the patients had biallelic mutations in the Shwachman-Bodian-Diamond syndrome gene (SBDS) located on chromosome 7(1,3).

The relative incidence of 1:76.538 live births suggests that SDS is relatively more common than previously thought(6). There is a higher prevalence in males with a ratio of 1.7:1(7-9)_{. The} frequency of SDS in Brazil is not known, nor is the presence of possible molecular changes associated with this pathology.

The aim of this report is to describe for the irst time the molecular diagnosis of a Brazilian child with SDS.

Case report

A 6-year-old boy was diagnosed with cystic ibrosis at the age of 15 months due to recurrent respiratory infections, diarrhea and therapeutic response to pancreatic enzymes. Three sweat tests were negative.

At the age of 5 years, the patient began to experience pain in the lower limbs, laxity of joints, lameness and frequent falls. There was no history of fractures, liver or kidney disease, use of medications associated with osteoporosis or rickets, lack of sunlight exposure, low calcium or vitamin D diet, or reports of metabolic bone disease or bone dysplasia in the family. There is no evidence for consanguinity. On physical examination his weight was 16 kg (10th centile), height 103 cm (5-10th centile), with P1/G1 Tanner pubertal stage. The liver was palpable 3 cm below the right costal margin. He also presented discrete genu varum, hyperextensible elbow joints and increased anteroposterior diameter of thorax. Review of medical records showed chronic leukopenia (leukocytes: 3.1-3.5 x 103_{/µL), neutropenia (segmented neutrophils:}

15-22%), but normal hemoglobin, hematocrit, and platelet count. A radiological study showed metaphyseal chondrodysplasia, sclerosis and pseudocysts in radial, humeral, ulnar, tibial and femoral metaphysis (Figure 1). Bone densitometry showed a z-score of -1.6.

Herein the irst molecular diagnosis of a Brazilian child with Shwachman-Diamond Syndrome is reported. A 6-year-old boy was diagnosed with cystic ibrosis at the age of 15 months due to recurrent respiratory infections, diarrhea and therapeutic response to pancreatic enzymes. Three sweat tests were negative. At the age of 5 years, he began to experience pain in the lower limbs, laxity of joints, lameness and frequent falls. A radiological study revealed metaphyseal chondrodysplasia. A complete blood cell count showed leukopenia (leukocytes: 3.1-3.5 x 103_{/µL), neutropenia (segmented neutrophils: 15-22%), but normal hemoglobin, hematocrit and platelet}

count. A molecular study revealed biallelic mutations in the Shwachman-Bodian-Diamond Syndrome gene (183-184TA-CT K62X in exon 2 and a 258+2T-C transition) conirming the diagnosis of Shwachman-Diamond Syndrome. A non-pathologic, silent nucleotide A to G transition at position 201 was also found in heterozygosis in the Shwachman-Bodian-Diamond Syndrome gene. This is the irst report to describe a Brazilian child with molecular diagnosis of Shwachman-Diamond Syndrome, a rare autosomal recessive disorder characterized by exocrine pancreatic insuficiency, intermittent or persistent neutropenia and skeletal changes. Other characteristics include immune system, hepatic and cardiac changes and predisposition to leukemia. Recurrent bacterial, viral and fungal infections are common. The possibility of Shwachman-Diamond Syndrome should be kept in mind when investigating children with a diagnosis of cystic ibrosis and normal sweat tests.

Keywords: Leukopenia/genetics; Exocrine pancreatic insuficiency/genetics; Cystic ibrosis; Bacterial

291 Rev Bras Hematol Hemoter. 2013;35(4):290-2

Shwachman-Diamond syndrome: irst molecular diagnosis in a Brazilian child

Evaluation of serum calcium, phosphorus, alkaline phosphatase, 25(OH)Vitamin D, 1,25(OH)Vitamin D, parathyroid hormone, liver and kidney function, thyroid function, electrolytes, lipase, amylase, blood sugar, immunoglobulin (IgG, IgA and IgM) and CD4 and CD8 lymphocyte counts were all normal. Hemoglobin electrophoresis showed: Hemoglobin (Hb) A1: 91.7%; Hb A2: 2.6%; Hb F: 5.7%. Blood sugar, insulin and an oral glucose tolerance test were normal, in spite of a raised glycated hemoglobin level of 6.5% (normal: < 5.6%). Fecal fat excretion tested positive and an abdominal ultrasound revealed increased pancreatic echogenicity. Sanger sequencing(8,9) demonstrated known pathogenic mutations in exon 2 of the SBDS gene: 183-184TA - CT K62X (Stop codon no exon 2) and 258+2T-C transition. In addition, a non-pathologic silent nucleotide A to G transition at position 201 in the SBDS gene was also detected in heterozygosis.

Discussion

The most common hematologic abnormality in SDS is persistent or intermittent neutropenia caused by bone marrow hypoplasia(1,10). Normochromic-normocytic anemia or macrocytic anemia with thrombocytopenia may occur. All these indings were present in this current case. Approximately 80% of patients have high levels of hemoglobin F(8). Bone marrow disease can progress to aplastic anemia, myelodysplastic syndrome or acute myeloid leukemia(1,7).

Recurrent bacterial, viral, and fungal infections, particularly, otitis, sinusitis, pneumonia, septicemia, osteomyelitis, and cutaneous infections are common. The main mechanisms responsible for these infections are neutropenia, defects in neutrophil chemotaxis, defects in lymphocyte-mediated immunity, reduced numbers of B cells, and low immunoglobulin (IgG) serum levels(1)_.

The pancreatic endocrine function is generally intact but exocrine pancreatic dysfunction caused by acinar cell hypoplasia is usually diagnosed in the irst year of life with intestinal malabsorption, steatorrhea, failure to thrive, and low levels of fat soluble vitamins(8). The diagnosis is conirmed by increased fecal fat excretion in the absence of cholestatic liver disease or intestinal failure, and by measurement of fecal elastase(8)_{. Trypsinogen}

is usually low in under 3-year-old children but normal in older patients. Moreover, the isoamylase serum is not useful in under 3-year-old children because serum levels are usually low in this age group(1). Imaging studies usually show a small pancreas

replaced predominantly by fat(4). Unlike cystic ibrosis, the sweat

test that measures the amount of chloride in the sweat is normal. Hepatomegaly is found in approximately 15% of patients, and 50-75% have elevated liver enzymes(1)_{. Hepatomegaly} and elevation of transaminases may eventually disappear, but cholestasis may persist and liver microcysts may develop in older patients(1). The patient described here had hepatomegaly, a

common feature in SDS.

The main skeletal abnormality is metaphyseal dysostosis involving the head of the femur, knees, humeral head, wrists, ankles and vertebrae(1)_{. The radiological study of this patient} showed metaphyseal chondrodysplasia of the radius, ulna, tibia and femur. Abnormalities of the rib cage, sliding femoral epiphysis, digit abnormalities, spinal deformities, osteopenia and osteoporosis have also been described. The patient described in this case report had increased anteroposterior diameter of the chest, a bone densitometry with a z-score of -1.6, and normal calcium, phosphorus, alkaline phosphatase and vitamin D.

Insulin-dependent diabetes, growth hormone deiciency, hypogonadotropic hypogonadism, hypothyroidism and short stature are endocrine changes described in SDS(11). Impaired

growth involves multiple factors including pancreatic insuficiency, feeding dificulties, recurrent infections and metaphyseal dysostoses. In this patient, glycated hemoglobin of 6.5% (upper normal limit) reinforces the need for vigilance regarding the development of diabetes.

The diagnosis of SDS is based on the clinical phenotype and is particularly challenging in older individuals in whom symptoms such as steatorrhea may have disappeared and the neutropenia may have changed to a cyclic pattern. Therefore, SDS should be suspected in children with poor weight gain, abnormal stools and neutropenia, as well as in any child suspected of having cystic ibrosis but with a negative sweat test(5). In spite of repeated negative sweat tests, this patient was being treated for cystic ibrosis.

Approximately 90% of patients have mutations of the SDS gene located in the 7q11 centromeric region of chromosome 7(1)_{. This gene apparently acts during the mitotic process by} promoting microtubule stabilization and actin polymerization, avoiding genomic instability and predisposition to neoplasias(1,7). Among several mutations described, the Ca. 258 + 2T and Ca. 183_184 TA>CT mutations correspond to 74% of the cases(12)_. Approximately 10% of patients do not show identiiable mutations in the SDS gene(3) meaning that a negative test does not rule out the syndrome. The molecular study in this patient’s report showed previously described mutations in exon 2 of the Figure 1 – Metaphyseal chondrodysplasia, sclerosis and pseudocysts in

292 Rev Bras Hematol Hemoter. 2013;35(4):290-2

Alves C, Fernandes JC, Sampaio S, Paiva RM, Calado RT

SBDS gene: 183-184TA-CT K62X (Stop codon in exon 2) and a 258+2T-C transition.

This is the irst report to describe the molecular diagnosis of SDS in a Brazilian child and highlights the need to investigate SDS in all children treated for cystic ibrosis with normal sweat tests.

References

1. Burroughs L, Woolfrey A, Shimamura A. Shwachman-Diamond syndrome: a review of the clinical presentation, molecular pathogenesis, diagnosis, and treatment. Hematol Oncol Clin North Am. 2009;23(2):223-48. 2. Donadieu J, Fenneteau O, Beaupain B, Beauils S, Bellanger F, Mahlaoui

N, Lambilliotte A, Aladjidi N, Bertrand Y, Mialou V, Perot C,Michel G, Fouyssac F, Paillard C, Gandemer V, Boutard P, Schmitz J, Morali A, Leblanc T, Bellanné-Chantelot C; Associated investigators of the French Severe Chronic Neutropenia Registry. Classiication of and risk

factors for hematologic complications in a French national cohort of 102

patients with Shwachman-Diamond syndrome. Haematologica. 2012; 97(9):1312-9. Comment in: Expert Rev Hematol. 2012;5(4):373-5. 3. Dall’oca C, Bondi M, Merlini M, Cipolli M, Lavini F, Bartolozzi P.

Shwachman-Diamond syndrome. Musculoskelet Surg. 2012;96(2):81-8. 4. Singh SA, Vlachos A, Morgenstern NJ, Ouansai I, Ip W, Rommens JM,

et al. Breast cancer in a case of Shwachman Diamond syndrome. Pediatr Blood Cancer. 2012;59(5):945-6.

5. Shwachman H, Diamond LK, Oski FA, Khaw KT. The syndrome of pancreatic insuficiency and bone marrow dysfunction. J Pediatr. 1964;65(5):645-63.

6. Goobie S, Popovic M, Morrison J, Ellis L, Ginzberg H, Boocock GR, et

al. Shwachman-Diamond syndrome with exocrine pancreatic dysfunction and bone marrow failure maps to the centromeric region of chromosome

7. Am J Hum Genet. 2001;68(4):1048-54.

7. Huang JN, Shimamura A. Clinical spectrum and molecular pathophysiology of Shwachman-Diamond syndrome. Curr Opin Hematol. 2010;18(1):30-5.

8. Dror Y, Donadieu J, Koglmeier J, Dodge J, Toiviainen-Salo S, Makitie O, et al. Draft consensus guidelines for diagnosis and treatment of Shwachman-Diamond syndrome. Ann N Y Acad Sci. 2011;1242:40-55. 9. Calado RT, Graf SA, Wilkerson KL, Kajigaya S, Ancliff PJ, Dror Y,

et al. Mutations in the SBDS gene in acquired aplastic anemia. Blood. 2007;110(4):1141-6.

10. Kopel L, Gutierrez PS, Lage SG. Dilated cardiomyopathy in a case of Shwachman-Diamond syndrome. Cardiol Young. 2011;21(5):588-90. 11. Akdogan MF, Altay M, Denizli N, Gucun M, Tanrikulu S, Duranay M.

A rare case: Shwachman Diamond syndrome presenting with diabetic

ketoacidosis. Endocrine. 2011;40(1):146-7.

12. Khan S, Hinks J, Shorto J, Schwarz MJ, Sewell WA. Some cases of common variable immunodeiciency may be due to a mutation in the SBDS gene of Shwachman-Diamond syndrome. Clin Exp Immunol. 2008;151(3):448-54.